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163 lines
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163 lines
7.5 KiB
Plaintext
//- 💫 DOCS > USAGE > TRAINING > OPTIMIZATION TIPS AND ADVICE
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p
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| There are lots of conflicting "recipes" for training deep neural
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| networks at the moment. The cutting-edge models take a very long time to
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| train, so most researchers can't run enough experiments to figure out
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| what's #[em really] going on. For what it's worth, here's a recipe that seems
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| to work well on a lot of NLP problems:
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+list("numbers")
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+item
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| Initialise with batch size 1, and compound to a maximum determined
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| by your data size and problem type.
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+item
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| Use Adam solver with fixed learning rate.
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+item
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| Use averaged parameters
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+item
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| Use L2 regularization.
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+item
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| Clip gradients by L2 norm to 1.
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+item
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| On small data sizes, start at a high dropout rate, with linear decay.
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p
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| This recipe has been cobbled together experimentally. Here's why the
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| various elements of the recipe made enough sense to try initially, and
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| what you might try changing, depending on your problem.
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+h(3, "tips-batch-size") Compounding batch size
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p
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| The trick of increasing the batch size is starting to become quite
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| popular (see #[+a("https://arxiv.org/abs/1711.00489") Smith et al., 2017]).
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| Their recipe is quite different from how spaCy's models are being
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| trained, but there are some similarities. In training the various spaCy
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| models, we haven't found much advantage from decaying the learning
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| rate – but starting with a low batch size has definitely helped. You
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| should try it out on your data, and see how you go. Here's our current
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| strategy:
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+code("Batch heuristic").
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def get_batches(train_data, model_type):
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max_batch_sizes = {'tagger': 32, 'parser': 16, 'ner': 16, 'textcat': 64}
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max_batch_size = max_batch_sizes[model_type]
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if len(train_data) < 1000:
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max_batch_size /= 2
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if len(train_data) < 500:
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max_batch_size /= 2
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batch_size = compounding(1, max_batch_size, 1.001)
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batches = minibatch(train_data, size=batch_size)
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return batches
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p
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| This will set the batch size to start at #[code 1], and increase each
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| batch until it reaches a maximum size. The tagger, parser and entity
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| recognizer all take whole sentences as input, so they're learning a lot
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| of labels in a single example. You therefore need smaller batches for
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| them. The batch size for the text categorizer should be somewhat larger,
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| especially if your documents are long.
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+h(3, "tips-hyperparams") Learning rate, regularization and gradient clipping
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p
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| By default spaCy uses the Adam solver, with default settings
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| (learning rate #[code 0.001], #[code beta1=0.9], #[code beta2=0.999]).
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| Some researchers have said they found these settings terrible on their
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| problems – but they've always performed very well in training spaCy's
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| models, in combination with the rest of our recipe. You can change these
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| settings directly, by modifying the corresponding attributes on the
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| #[code optimizer] object. You can also set environment variables, to
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| adjust the defaults.
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p
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| There are two other key hyper-parameters of the solver: #[code L2]
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| #[strong regularization], and #[strong gradient clipping]
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| (#[code max_grad_norm]). Gradient clipping is a hack that's not discussed
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| often, but everybody seems to be using. It's quite important in helping
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| to ensure the network doesn't diverge, which is a fancy way of saying
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| "fall over during training". The effect is sort of similar to setting the
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| learning rate low. It can also compensate for a large batch size (this is
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| a good example of how the choices of all these hyper-parameters
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| intersect).
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+h(3, "tips-dropout") Dropout rate
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p
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| For small datasets, it's useful to set a
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| #[strong high dropout rate at first], and #[strong decay] it down towards
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| a more reasonable value. This helps avoid the network immediately
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| overfitting, while still encouraging it to learn some of the more
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| interesting things in your data. spaCy comes with a
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| #[+api("top-level#util.decaying") #[code decaying]] utility function to
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| facilitate this. You might try setting:
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+code.
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from spacy.util import decaying
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dropout = decaying(0.6, 0.2, 1e-4)
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p
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| You can then draw values from the iterator with #[code next(dropout)],
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| which you would pass to the #[code drop] keyword argument of
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| #[+api("language#update") #[code nlp.update]]. It's pretty much always a
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| good idea to use at least #[strong some dropout]. All of the models
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| currently use Bernoulli dropout, for no particularly principled reason –
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| we just haven't experimented with another scheme like Gaussian dropout
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| yet.
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+h(3, "tips-param-avg") Parameter averaging
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p
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| The last part of our optimization recipe is #[strong parameter averaging],
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| an old trick introduced by
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| #[+a("https://cseweb.ucsd.edu/~yfreund/papers/LargeMarginsUsingPerceptron.pdf") Freund and Schapire (1999)],
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| popularised in the NLP community by
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| #[+a("http://www.aclweb.org/anthology/P04-1015") Collins (2002)],
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| and explained in more detail by
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| #[+a("http://leon.bottou.org/projects/sgd") Leon Bottou]. Just about the
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| only other people who seem to be using this for neural network training
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| are the SyntaxNet team (one of whom is Michael Collins) – but it really
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| seems to work great on every problem.
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p
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| The trick is to store the moving average of the weights during training.
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| We don't optimize this average – we just track it. Then when we want to
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| actually use the model, we use the averages, not the most recent value.
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| In spaCy (and #[+a(gh("thinc")) Thinc]) this is done by using a
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| context manager, #[+api("language#use_params") #[code use_params]], to
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| temporarily replace the weights:
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+code.
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with nlp.use_params(optimizer.averages):
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nlp.to_disk('/model')
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p
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| The context manager is handy because you naturally want to evaluate and
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| save the model at various points during training (e.g. after each epoch).
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| After evaluating and saving, the context manager will exit and the
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| weights will be restored, so you resume training from the most recent
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| value, rather than the average. By evaluating the model after each epoch,
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| you can remove one hyper-parameter from consideration (the number of
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| epochs). Having one less magic number to guess is extremely nice – so
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| having the averaging under a context manager is very convenient.
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+h(3, "tips-transfer-learning") Transfer learning
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p
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| Finally, if you're training from a small data set, it's very useful to
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| start off with some knowledge already in the model. #[strong Word vectors]
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| are an easy and reliable way to do that, but depending on the
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| application, you may also be able to start with useful knowledge from one
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| of spaCy's #[+a("/models") pre-trained models], such as the parser,
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| entity recogniser and tagger. If you're adapting a pre-trained model and
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| you want it to retain accuracy on the tasks it was originally trained
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| for, you should consider the "catastrophic forgetting" problem.
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| #[+a("https://explosion.ai/blog/pseudo-rehearsal-catastrophic-forgetting", true) See this blog post]
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| to read more about the problem and our suggested solution,
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| pseudo-rehearsal.
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